We give a simple sufficient condition for a weighted graph to have a diameter-preserving spanning tree. More precisely, let G = (V, E, fE) be a connected edge weighted graph with fE being the edge weight function. Let fV be the vertex weight function of G induced by fE as follows: fV(v) = max{fE(e) : e is incident with v} for all $${v \in V}$$ . We show that G contains a diameter-preserving spanning tree if $${d(G)\ge \frac{2}{3} \sum_{v\in V} f_V(v)}$$ where d(G) is the diameter of G. The condition is sharp in the sense that for any $${\epsilon >0 }$$ , there exist weighted graphs G satisfying $${d(G) > (\frac{2}{3}-\epsilon)\sum_{v\in V} f_V(v)}$$ and not containing a diameter-preserving spanning tree.
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